温敏核不育系培矮64S及其eui突变体长选3S最上节间蛋白质组差异分析

为从蛋白质表达水平了解长穗颈温敏核不育水稻(Oryza sativa)最上节间伸长机理,采用双向凝胶电泳方法对温敏核不育系培矮64S及其eui突变体长选3S抽穗前2 d的最上节间蛋白质进行了分离,并获得了分辨率和重复性较好的双向凝胶电泳图谱。选取50个差异蛋白质点进行MALDI-TOF-TOF-MS肽质谱指纹图谱分析,从中鉴定出31个已知蛋白质,相对于培矮64S,在长选3S中上调表达的11个蛋白质和下调表达的20个蛋白质。这些差异蛋白质按照其功能可分为7类。这些差异蛋白质可能与长选3S抽穗期最上节间剧烈伸长生长有关,水稻eui基因可能是通过调节抽穗期最上节间这些蛋白质的表达,从而控制最上节间细胞分裂,尤其是细胞的伸长生长。     

温度对长穗颈温敏核不育水稻(Oryza sativa L.)穗颈伸出长度的影响

以隐性长穗颈温敏核不育水稻(OryzasativaL)长选3S为材料,研究了温度对隐性长穗颈温敏核不育水稻长选3S穗颈伸出长度的影响。结果表明:人工24℃条件下,在始花前第12天至始花前第4天和始花当天至始花后第3天两个时段,穗颈节间伸长速度慢,两者节间日均伸长长度基本一致,但从始花前第4天至始花当天,长选3S穗颈节间伸长速度最快,其节间日均伸长的长度是培矮64S的2.1倍。在敏感期分别进行22、24、26、28℃4种人工温度处理,28℃条件下穗颈节间伸长受阻,出现包颈现象;26～22℃条件下穗颈伸出长度都为正值,不包颈,但穗颈伸出剑叶叶鞘的长度随温度降低而增加。通过对穗颈节间细胞数目和细胞长度的比较分析表明,长选3S穗颈节间的伸长主要是由于细胞分裂和细胞伸长共同作用所致,其中后者作用更显著,且随处理温度的升高,穗颈节间最内和最外层薄壁细胞数目减少,细胞平均长度变短。     

长穗颈不育水稻穗颈节间的细胞学研究

通过对长选3S和培矮64S定长的穗颈节间细胞个数统计和细胞长度的测量,得出长穗颈不育水稻穗颈节间伸长的细胞学变化规律.自然条件下长穗颈不育水稻长选3S穗颈节间比对照培矮64S长18.0cm,其纵列厚壁细胞和薄壁细胞数分别比培矮64S多1248个和580个;厚壁细胞和薄壁细胞平均长度分别比培矮64S长23.3μm和38.3μm,尤其是中部区段的厚壁细胞和薄壁细胞分别比对照长24.8μm和48.7μm;穗颈节间薄壁细胞的长度由基部区段至中部区段呈突跃式增加,而由中部至顶部区段则呈缓慢减少的趋势.隐性长穗颈温敏核不育水稻穗颈节间伸长是由细胞数目增多和细胞长度增加双重作用所致,其中后者作用更显著.     

隐性长穗颈光敏核不育水稻最上节间伸长动态规律的研究

隐性长穗颈性状具有解除雄性不育水稻包颈现象的作用,因此在杂交制种中具有较高的应用价值.以培矮64S为对照,研究了隐性长穗颈光敏核不育水稻长光S最上节间伸长的动态规律,结果表明最上节间伸长的时期为始花前6d至始花当天.始花前1～3d为节间快速伸长期,此时期主要由节间中下部细胞大幅度伸长所致.长光S细胞长度与培矮64S细胞长度差异主要体现在节间快速伸长期.花粉正常发育具有促进节间快速伸长期细胞伸长的作用,隐性长穗颈基因与花粉正常发育在促进节间快速伸长期细胞伸长的作用中有互作增效作用.     

长穗颈温敏核不育水稻穗颈节间长度及细胞学观察

以水稻培矮64S作对照,对隐性长穗颈温敏核不育水稻(Oryza sativa L.)长选3S幼穗各发育时期穗颈节间长度及细胞数量和长度进行比较分析。结果表明,长选3S在幼穗分化的二核期至始花期穗颈节间伸长速度最快,其节间伸长的长度是培矮64S的2.1倍;在花粉母细胞减数分裂期至二核期及始花当天至始花后第3天两个时段,穗颈节间伸长速度慢。穗颈节间的细胞个数和平均长度两者呈现相似的变化规律,但从花粉母细胞减数分裂期至始花期,长选3S穗颈节间薄壁细胞增加3759个,细胞平均长度为72.9μm,培矮64S增加3134个,细胞平均长度为38μm,长选3S穗颈节间的伸长主要是由幼穗分化的花粉母细胞减数分裂期至始花期细胞分裂和细胞伸长共同作用的结果,其中后者的作用更显著。     

‘培矮64S’与其eui突变体‘长选3S’穗颈节间蛋白质组差异分析

为从蛋白质表达水平了解长穗颈温敏核不育水稻穗颈节间伸长机理,该研究以长穗颈(EUI)温敏核不育水稻‘长选3S’为材料,温敏核不育水稻‘培矮64S’为对照,采用固相pH梯度双向凝胶电泳和质谱分析方法,对2个水稻材料抽穗前2 d的穗颈节间蛋白质进行分离,并进行差异蛋白质组学的比较研究。结果表明:(1)获得了分辨率和重复性较好的双向凝胶电泳图谱。(2)对40个差异蛋白质点进行MALDI-TOF-TOF-MS肽质谱指纹图谱分析,成功鉴定其中27个差异蛋白质点;与‘培矮64S’相比,‘长选3S’中有17个上调表达和10个下调表达的蛋白质。(3)差异蛋白质按照其功能可分为6类,其中主要是与细胞代谢相关蛋白,其次是与细胞壁重建相关蛋白;并且这些差异蛋白质可能与‘长选3S’抽穗期穗颈节间剧烈伸长生长有关,尤其是细胞壁重建相关蛋白与细胞的伸长密切相关。(4)实时荧光定量PCR对随机挑选的蛋白点2、7、8、24、35和36所对应的基因在两个材料最上节间的表达结果显示,‘长选3S’的2(Os10g08550)、7(Os12g42876)、8(Os01g55830)基因的表达量较‘培矮64S’明显下调,而24(Os06g48760)、35(Os05g25850)、36(Os07g42300)基因的表达量较‘培矮64S’显著上调,表明q-PCR的结果与蛋白凝胶图分析结果一致。研究认为,水稻eui基因可能是通过调节抽穗期穗颈节间这些蛋白质的表达,从而促进穗颈节间细胞分裂,尤其是细胞的伸长生长。     

水稻长穗颈eui突变体长选3S最上节间基因差异表达研究

利用水稻全基因组芯片和半定量PCR对水稻长穗颈eui突变体长选3S与对照培矮64S最上节间快速伸长期的基因差异表达分析,在检测到的56 983芯片杂交点只发现527个差异表达转录本,其中上调表达的362个,下调表达的165个.生物信息分析发现,差异表达的转录本包括信号传导相关基因、膜及运输基因、细胞生长与凋亡相关基因、复制与修复相关基因、碳代谢相关基因,次生代谢物合成相关基因和其它功能未知基因.研究结果为了解水稻最上节间伸长机制提供了非常有用的信息.     

温度对双低两用核不育水稻96-5-2S与培矮64S育性的影响

在自然变温、人工控温及冷水灌溉条件下,比较研究了温度对双低两用核不育水稻96－5－2S与两用核不育水稻培矮64S育性影响的差异。结果表明：（1）当它们在雄性育性转换温敏感期1－12d平均自然日均温23.0-23.8℃的低温时,96－5－2S表现不良,套袋自交结实率为0,而培矮46S可育,套袋自交结实率为0．1％－4．5％;（2）在它们雄性育性转换温敏感期用22℃恒温处理5d,96－5－2S败育彻底,套袋自交结实率为0,而培矮64S可育,套袋自交结实率为10．7％;用17℃恒温处理6d,96－5－2S与培矮64S均可育,但96－5－2S套袋自交结实率（6．8％）显著高于培矮64S（2．5％）;（3）在它们雄性育性转换温和不同温度的冷水串灌15d,水深维持在20cm左右,当水温为22－22．5℃时,96－5－2S不育,结实率为0,而培矮64S可育,结实率为18．5％;当水温为19．5－21．5℃时,96－5－2S与培矮64S均可育,但96－5－2S结实率（2．5％－45．1％）显著或极显著低于培矮64S（50．4％－56．9％）以上结果说明：导致双低两用核不育水稻96－5－2S雄性不育的起点温度与导致其生理不育的下限温度均低,其不育性比培矮64S更稳定,耐寒性比培矮64S更强,即可确保制种安全,又可确保自身繁殖,对加快两系法杂交水稻的发展步伐将起到重要的促进作用。     

两个籼型水稻核不育系育性温光反应的研究

在杭州男单通过分期播种,比较了两个籼稻光温敏核不育系的育性及其转换特性。结果表明,光照长度对浙大247S和培矮64S两不育系育性表达的影响小,温度起主导作用,均属温敏型不育系,且日最低温度对不育系育性效应显著高于日平均温度和日最高温度。不育系浙大247S和培矮64S的温度敏感期分析是抽穗前3-18和6-21d,育性转换的临界日期为9月19日和9月25日,转换临界温度为25.28和25.66℃,与培矮64S相比,浙大247S不育期败育较彻底,可育期较长且自交结实率高,在杭州田间可以繁种。     

温敏核不育水稻穗颈节间的SSH特异表达

‘长选3S’是由‘培矮64S’通过辐射诱变选育出的长穗颈温敏核不育水稻．以‘K选3s’二核花粉期穗颈节问作为目标群体,‘培矮64S’二核花粉期穗颈节间作为对照群体,进行抑制差减杂交,川经过‘培矮64S’cDNA差减的‘长选3S’cDNA构建了一个含有大约130个独立克隆的差减文库;采用差减前的‘培矮64S’cDNA和‘长选3S’cDNA以及正向／反向差减杂交后的cDNA为模板标记探针,对随机挑取的96个承组质粒进行羞示筛选,获得了20个阳性候选克隆。从这些阳性候选克隆中随机挑取了8个进行Northern blot分析．证实其巾中1个候选克隆代表了在‘长选3S’穗颈节间中特异表达的基因．序列分析和同源性比较表明它与信号传导有关。这一在‘长选3S’穗颈节间特异表达的cDNA片段有助于进一步揭示其穗颈节间伸长的分子机制．并为水稻不育系的遗传改良提供有用的素材。     

Genetic and Microsatellite Analyses of a New Elongated Uppermost Internode Gene Teui2 of Rice

Two mutants possessing elongated uppermost internode, Xieqingzao eB-1 (XQZeB-1) and Xieqingzao eB-2 (XQZeB-2), were identified from M 2 population of Xieqingzao B-line (XQZB) treated with γ-ray. The proportion of uppermost internode length to entire culm length of XQZeB-2 and XQZeB-1 were 65.3%and 54.8%, respectively. Compared with the original XQZB, the increased length of uppermost internode of XQZeB-2 contributed to the total increased culm length by 90.2% as well as XQZeB-1 by 53.3%. Genetic analysis showed that the characters of elongated uppermost internode in the two mutants were governed by one pair of recessive gene respectively. The recessive gene of XQZeB-1 is allelic to the reported eui , but that of XQZeB-2 is non-allelic to it by allelic test. Therefore, the elongated-uppermost-internode gene of XQZeB-2 is a new gene, designated as eui2. Microsatellite markers RM258, RM269, RM271 and RM304, which were linked with eui2 and located on chromosome 10, were identified. The genetic distances from the four markers to eui2 were 12.0 cM, 12.9 cM, 35.1 cM, 1.4 cM, respectively. It could be concluded that eui2 gene was located on the middle of the long arm of chromosome 10.     

Fine Mapping and in silico Isolation of the EUI1 Gene Controlling Upper Internode Elongation in Rice

Upper internode elongation in rice is an important agronomic trait. Well-known mutants with an elongated uppermost internode (eui) are important germplasms for developing unsheathed-panicle male-sterile lines in hybrid rice breeding. We finely mapped the eui1 gene and identified its candidate gene using in silico analysis based on previous research work and rice genomic sequence data. The rice eui1 gene was mapped to two overlapping BAC clones, OSJNBa0095J22 and OSJNBb0099O15, between the markers AC40 and AC46, that were 0.64 cM apart and spanned approximately 152 kb. A simple sequence repeat (SSR) marker AC41 that cosegregated with eui1 was located in an intron of a putative cytochrome P450-related gene. In silico analysis suggested that this encoded the cytochrome CYP714D1. Allelic sequencing confirmed that EUI1 corresponded to this P450 gene. A gamma ray-induced eui1 mutant carried a deletion in exon II of the EUI1 gene, and resulted in a frame-shift deletion that produced a truncated polypeptide. We conclude that the EUI1 gene controlling the upper internode elongation in rice is 9804 bp long, and comprises two exons and one intron. The length of the cDNA is 1931 bp containing a 1734 bp ORF, a 110 bp 5′-UTR and a 87 bp 3′-UTR. The ORF encodes an unknown 577 amino acid functional protein, that appears to be a member of the cytochrome P450 family. Hongli Ma, Shubiao Zhang: These authors contributed equally to this work     

长穗颈水稻的内源GA1、IAA和ABA含量变化

分别以携有长穗颈基因eui1、eui2和野生型基因Eui的协青早不育系和保持系6个水稻品种为材料,测定它们在抽穗始期植株中内源GA1、IAA和ABA含量的变化。结果表明,携有eui1和eui2基因的水稻可以在植株体内产生大量内源GA1,携有eui1基因的GA1含量比携有eui2基因的高。携有eui1基因的ABA含量最高,携有eui2基因的其次,而携有Eui基因的最低。IAA含量也表现出同样的趋势。表明长穗颈基因主要是通过调节内源GA1含量促进水稻最上节间的剧烈伸长。     

Phosphatidylserine Synthase Controls Cell Elongation Especially in the Uppermost Internode in Rice by Regulation of Exocytosis

The uppermost internode is one of the fastest elongating organs in rice, and is expected to require an adequate supply of cell-wall materials and enzymes to the cell surface to enhance mechanical strength. Although it has been reported that the phenotype of shortened uppermost internode 1 (sui1) is caused by mutations in PHOSPHATIDYLSERINE SYNTHASE (OsPSS), the underlying mechanism remains unclear. Here we show that the OsPSS-1, as a gene expressed predominantly in elongating cells, regulates post-Golgi vesicle secretion to intercellular spaces. Mutation of OsPSS-1 leads to compromised delivery of CESA4 and secGFP towards the cell surface, resulting in weakened intercellular adhesion and disorganized cell arrangement in parenchyma. The phenotype of sui1-4 is caused largely by the reduction in cellulose contents in the whole plant and detrimental delivery of pectins in the uppermost internode. We found that OsPSS-1 and its potential product PS (phosphatidylserine) localized to organelles associated with exocytosis. These results together suggest that OsPSS-1 plays a potential role in mediating cell expansion by regulating secretion of cell wall components.     

EUI1, encoding a putative cytochrome P450 monooxygenase, regulates internode elongation by modulating gibberellin responses in rice

Elongation of rice internodes is one of the most important agronomic traits, which determines the plant height and underlies the grain yield. It has been shown that the elongation of internodes is under genetic control, and various factors are implicated in the process. Here, we report a detailed characterization of an elongated uppermost internode1 (eui1) mutant, which has been used in hybrid rice breeding. In the eui1-2 mutant, the cell lengths in the uppermost internodes are significantly longer than that of wild type and thus give rise to the elongated uppermost internode. It was found that the level of active gibberellin was elevated in the mutant, whereas its growth in response to gibberellin is similar to that of the wild type, suggesting that the higher level accumulation of gibberellin in the eui1 mutant causes the abnormal elongation of the uppermost internode. Consistently, the expression levels of several genes which encode gibberellin biosynthesis enzymes were altered. We cloned the EUI1 gene, which encodes a putative cytochrome P450 monooxygenase, by map-based cloning and found that EUI1 was weakly expressed in most tissues, but preferentially in young panicles. To confirm its function, transgenic experiments with different constructs of EUI1 were conducted. Overexpression of EUI1 gave rise to the gibberellin-deficient-like phenotypes, which could be partially reversed by supplementation with gibberellin. Furthermore, apart from the alteration of expression levels of the gibberellin biosynthesis genes, accumulation of SLR1 protein was found in the overexpressing transgenic plants, indicating that the expression level of EUI1 is implicated in both gibberellin-mediated SLR1 destruction and a feedback regulation in gibberellin biosynthesis. Therefore, we proposed that EUI1 plays a negative role in gibberellin-mediated regulation of cell elongation in the uppermost internode of rice.     

Chemical Composition of Phloem Sap from the Uppermost Internode of the Rice Plant

The chemical composition of phloem sap from the uppermost internodeof rice plants (Oryza sativa L., var. Kantou), one week afteranthesis, was compared with that of phloem sap from the leafsheath of a young seedling. The pure phloem sap from rice plantswas collected by an insect laser technique. The phloem sap from the uppermost internode contained a highlevel of sucrose (573.8 mM) which was the only sugar detected.The concentrations of total amino acids, potassium and ATP were124.8 mM, 40.4 mM and 1.76 mM, respectively. The concentrationof sucrose was three times higher and the potassium level wasone third as high in the internode sap as in the phloem sapfrom the leaf sheath. The total concentration of amino acidswas almost the same, but the relative amount of each amino acidwas quite different. The ratios of levels of Glu to Gln andof levels of Asp to Asn in the phloem sap from the uppermostinternode were smaller than those in the phloem sap from theleaf sheath. The adenylate energy charge was 0.92–0.93in both types of phloem sap. The amino acid composition of the phloem sap from the uppermostinternode was compared with that of the phloem sap of the flagleaf and the endosperm sap of the same plant, one week afteranthesis. The differences in composition along the phloem pathwaysuggest the selective translocation of amino acid. (Received July 21, 1989; Accepted December 11, 1989)     

水稻顶节间长度控制基因(EUI)的精细定位

通过对一水稻顶节间特异伸长突变体Mh-1进行经典遗传学和基因定位分析,认为该表型是一个核基因隐性突变所致。利用Mh-1与正常的T65-sd1杂交的F2群体对该位点定位研究分析,发现其与水稻第5条染色体长臂STS标记E30531和CAPS标记C903连锁,遗传距离分别为6．7cM和2．8cM。经进一步发展新的分子标记,将该基因精确定位在0．3cM的区域,为进一步克隆和研究该基因的分子机制奠定基础。     

Identification and characterization of SHORTENED UPPERMOST INTERNODE 1, a gene negatively regulating uppermost internode elongation in rice

In rice, the elongated internodes are derived from the vegetative shoot apical meristem (SAM), and the transition of the SAM from the vegetative to the reproductive stage induces internode elongation. In this study, we characterize two shortened uppermost internode mutants (sui1-1 and sui1-2). During the seedling and tillering stages, sui1 plants are morphologically similar to wild-type plants. However, at the heading stage, the sui1-1 mutant exhibits a shortened uppermost internode and a partly sheathed panicle, and the sui1-2 mutant shows an extremely shortened uppermost internode and a fully sheathed panicle. Gibberellin treatment results in elongation of every internode, but the shortened uppermost internode phenotype remains unaltered. Microscopic analysis indicates that cell length of sui1-1 uppermost internode exhibits decreased. Map-based cloning revealed that SUI1 is located on Chromosome 1, and encodes a putative phosphatidyl serine synthase (PSS) family protein. Searches for matches in protein databases showed that OsSUI1 contains the InterPro domain IPR004277, which is conserved in both animal and plant kingdoms. Introduction of a wild-type SUI1 gene fully rescued the mutant phenotype of sui1-1 and sui1-2, confirming the identity of the cloned gene. Consistent with these results, the SUI1-RNAi transgenic plants displayed decreased elongation of the uppermost internode. Our results suggest that SUI1 plays an important role in regulating uppermost internode length by decreasing longitudinal cell length in rice.     

水稻长穗颈基因eui紧密连锁SSR标记获得

02428h是从半矮秆材料02428体细胞培养后代中发现的隐性高秆突变体, 其株高性状由1对长穗颈基因eui和1对半矮秆基因sd-1共同控制。以02428h与半矮秆材料南京11杂交的F₂为作图群体, 利用Gramene公布的SSR标记和根据NCBI中的BAC序列自己新开发的SSR标记, 将eui基因定位在第5染色体上的RM3673和RM0012之间, 两侧遗传距离分别为0.3 cM和1.0 cM, 为该基因的分子标记辅助选择奠定了基础。     

Fine mapping of a gene for non-pollen type thermosensitive genic male sterility in rice (Oryza sativa L.)

The thermo-sensitive genic male sterility (TGMS) lines play a crucial role in two-line hybrid rice production. For a practical TGMS line, the stability of male sterility is one of the most important technical indicators. In this study, XianS, a spontaneous mutant with stable male sterility from an indica rice cultivar Xianhuangzhan, was classified as a non-pollen type TGMS line. The critical non-pollen sterility point temperature of XianS was determined as 27°C. Genetic analysis demonstrated that the non-pollen sterility in XianS was controlled by a single recessive gene. Using SSR markers and bulked segregant analysis, the TGMS gene in XianS was fine mapped to a 183 kb interval between RMAN81 and RMX21 on chromosome 2. Two markers, 4039-1 and RMX14 completely cosegregated with this gene. Allelism test indicated that the non-pollen phenotype in seven non-pollen type TGMS lines from different sources, XianS, AnnongS-1, Q523S, Q524S, N28S, G421S, and Q527S is caused by the same TGMS gene. Although the location of TGMS gene in XianS is close to the gene OsNAC6, a previously identified candidate gene of tms5 in AnnongS-1, the sequence of OsNAC6 and its promoter region was identical in TGMS line XianS, AnnongS-1, and wild-type Xianhuangzhan. These results suggest that the non-pollen type TGMS trait probably be controlled by the same TGMS gene in different TGMS rice lines, but its real candidate gene still need to be further studied and identified.